EP1520484A1

EP1520484A1 - Method for obtaining a monodisperse foam, and product obtainable by such method

Info

Publication number: EP1520484A1
Application number: EP04077755A
Authority: EP
Inventors: Albert Thijs Poortinga; Hendrika Koman-Boterblom; Maria Elisabeth Wijnen
Original assignee: Friesland Brands BV
Current assignee: FrieslandCampina Nederland BV
Priority date: 2003-10-02
Filing date: 2004-10-04
Publication date: 2005-04-06
Anticipated expiration: 2024-10-04
Also published as: DE602004022752C5; EP1520485B1; EP1520485A1; DE602004031700D1; EP1520484B1; DE602004022752D1; ATE440503T1; ES2332512T3; ATE500745T1

Abstract

A method for manufacturing a substantially monodisperse foam, wherein from an unfoamed liquid starting product, in a first foam forming step, a relatively coarse prefoam is formed which is insufficiently monodisperse, wherein the prefoam is passed through a membrane having a particular pore diameter to form a foam which is substantially monodisperse.

Description

The invention relates to a method for obtaining a monodisperse foam. A monodisperse foam is understood to mean a foam in which the bubbles present therein have substantially the same dimensions.
There is a wide need for healthy food products having a unique taste and a unique mouthfeel. Over the last years, the products having a low fat content have become popular because of health aspects. However, such products often lack the taste and the mouthfeel of whole products.
It is known that the taste sensation and the mouthfeel of foods can be considerably influenced by the presence of bubbles. Adding gas bubbles to a product moreover provides the possibility of low-fat products having improved sensory properties. The sensory properties can be controlled inter alia in the area of creaminess, freshness, softness or airiness. Which sensory property is influenced, and in what way and to what extent, depends inter alia on the size and the number of bubbles. Thus, the attribute of creaminess in a mousse is more enhanced when smaller bubbles are present in not too high numbers. The attribute of airiness in mousse is more enhanced when larger bubbles are present in higher numbers. In this light, see for instance Kilcast & Clegg in Food Quality and Preference 13 (2002), 609-623.
The appearance of a foamed product is also partly determined by the amount of bubbles and the bubble size in the foam.
Foamed products have already been known in the market for decades. Examples are mousses, whipped cream, ice-cream, shakes and desserts. Such products generally have a more or less fixed structure which enables the bubbles to be retained in the product for the required, at least desired, storage time of a few weeks up to months. Pourable foamed products are less well known. Generally, such products, for instance soft drinks, have a foam stability of the order of a few seconds instead of a few weeks. To prepare foamed, pourable products in which the bubbles remain present for a few weeks up to months, small bubbles are required.
It is often preferred that a foamed product be stable, at least during the time that it can be used, and consumed in the case of foods.
The term "stability" in this connection points to the possibility of storing the foamed product for a longer time without ongoing changes in the size of the gas bubbles present leading to undesired coarsening and/or possibly to creaming of the gas bubbles and/or other unwanted structural changes.
Foamed products are by definition thermodynamically unstable. The three most important destabilization processes that occur are creaming, coalescence and disproportionation of the foam-forming gas bubbles.
Creaming of bubbles can be controlled in practice by setting a proper ratio between bubble size and product viscosity.
Coalescence of two bubbles to form one larger bubble occurs especially when the product film between two bubbles is very thin. In products in which relatively little gas is distributed, such as pourable foamed products, coalescence is mostly not a great problem.
Disproportionation, also known as Ostwald ripening, involves larger bubbles growing out at the expense of smaller bubbles. It is a result of gas diffusion between bubbles of different size, and between bubbles and the environment. As a result of the coarsening of the gas bubbles present, the appearance changes significantly and moreover the driving force towards creaming becomes greater. As a result, the stability of the foam can deteriorate dramatically.
Stabilization of pourable foamed products against disproportionation will, in practice, hardly if at all be realized by the rheological properties of the continuous phase, as is the case, for instance, with mousse, where stabilization is partly determined by the gelatin network present. In the case of pourable foamed products, the long-term stabilization against disproportionation can be realized by the surface properties of the bubble surfaces. The simultaneously filed Dutch patent application 1024435 entitled: "Method for stabilizing an edible foam; the stable foam; and compositions comprising such foam" provides a solution to that end. The content of that patent application is understood to be incorporated herein by reference.
Another possibility of increasing the stability of a foamed product can be realized by arranging for the variation in bubble size to be as small as possible.
The present invention contemplates a method by means of which a foam is obtained whose bubbles are substantially equally large. Additionally contemplated is achieving this object with a least possible energy consumption.
According to the invention, a method for manufacturing a substantially monodisperse foam is provided, wherein from an unfoamed starting product, in a first foam forming step, a (relatively coarse) prefoam is formed which is insufficiently monodisperse, wherein the prefoam is passed through a membrane having a particular pore diameter for forming a foam which is substantially monodisperse. Incidentally, eligible for use as membrane is in fact any permeable material in which the perforations are such that a monodisperse foam remains. To that end, the pore size must be less than the desired bubble size. Very good properties are obtained when using membranes having a thickness of at least 30 times the pore radius, more preferably at least 50 times the pore radius and most preferably at least 100 times the pore radius.
The fine thing about the method according to the invention is that the bubble size of the foam obtained with the method can be controlled on the basis of the proper choice of the pore size of the membrane. Accordingly, when the starting product is a food, the desired sensory properties can be obtained with the method according to the invention. Moreover, the method according to the invention takes particularly little energy. When a prefoam with bubble sizes of between 30 and 250 micrometers is passed through a membrane of an average pore size of 8 micrometers, the energy required for that is about 2.5 kJ per liter of foam. To obtain such a decrease in bubble size utilizing the Mondomix rotor-stator mixer, known per se, an amount of energy of 500 kJ per liter of foam is needed. The foregoing figures show clearly that a considerable saving of energy is obtained in the method according to the invention, in addition to the other advantages, described above.
According to a further elaboration of the invention, the average pore diameter of the membrane is chosen to be substantially ten times smaller than the desired bubble diameter of the substantially monodisperse foam. Thus, through a choice of the proper pore size, the bubble size of the foam can be defined. The invention further provides a method for imparting particular sensory characteristics to an edible foamed product utilizing the above-described method, wherein the sensory properties are set through a suitable choice of the bubble size of the foam, wherein this bubble size is determined by choosing the pore size of the membrane to be about ten times smaller than the desired bubble size.
According to a further elaboration of the invention, the prefoam can be produced by a standard commercially available foaming device. To be considered here, for instance, is the well-known Mondomix rotor-stator mixer. It is also possible, however, that the prefoam is produced utilizing any other method that forms a non-monodisperse foam.
According to a further elaboration of the method, it is preferred that the denaturation and the compression of the bubbles take place after the foam has passed the membrane. This can be realized, for instance, in that the foam, after it has passed the membrane, is heated at a temperature and for a time which have been selected to be such that denaturation occurs.
Incidentally, these embodiments are described in detail in the Dutch patent applications NL 1024435, NL 1024434 and NL 1024438, filed simultaneously with the present application.
The contents of these patent applications and in particular the subject matter of each of the claims 1 of these applications are understood to be incorporated herein by reference. What is effected in particular by the use of the methods from the simultaneously filed patent applications is that after or during the foaming of the product, proteins from the unfoamed starting product, upon adsorption to the bubble surfaces, denature, after which the thus formed protein layer compresses upon allowing the bubble to shrink, so that an undeformable, at least rigid, surface is formed around the gas bubbles.
According to a further elaboration of the invention, the pore size of the membrane is in the range of 0.1-20 micrometers, more in particular in the range of 0.2-10 micrometers. With such a membrane, a monodisperse foam is obtained whose average bubble size varies between 1 and 100 micrometers, more preferably between 3 and 30 µm, starting from a prefoam in which the average bubble dimensions vary from 30 to 250 micrometers.
According to a further elaboration of the invention, the viscosity of the prefoam can be increased by adding a thickener to it, such as, for instance, xanthan gum. Such a thickener prevents the bubbles from creaming and thus leaving the product. According to a further elaboration of the method, the prefoam contains at least substantially 20% of gas. However, also lower or higher overrun percentages can be used. The starting product generally comprises a solution of surface-active substances which stabilize the bubbles and in particular prevent disproportionation. Examples are sugar esters, TWEEN®, and stabilizing proteins.
According to a further elaboration of the invention, the membrane that is used can be, for instance, a sintered metal membrane. The use of a ceramic membrane or a polymer membrane also belongs to the possibilities.
According to a further elaboration of the invention, it is preferred to arrange for the minimum bubble size in the prefoam to be about 5 times greater than the average pore size. What is accomplished in this way is that all bubbles in the prefoam break up in the membrane and are transformed into smaller bubbles. This provides the advantage that the bubble size in the monodisperse foam can be controlled very accurately through the proper choice of the bubble size of the prefoam and the pore size of the membrane.
According to a further elaboration of the invention, it is preferred that in the foamed product about 3 to 10 milligrams of protein are included per m² of bubble surface. In addition, in that case, at least about 0.1 wt.% of protein should be in the solution, so that the proteins present on the bubble surface, if necessary, can be supplemented from the solution.
The method is advantageous in particular when the starting product is a milk protein-containing edible liquid.
The invention further concerns a product obtainable with the method according to the invention.
Such a product maintains its foam structure over a longer time in that the bubbles have substantially the same size, so that disproportionation proceeds more slowly. Moreover, in the case of an edible product, through the use of the method, a product can be obtained that has the desired taste and structural properties.
The invention will presently be elucidated in and by a number of examples.

Example 1

Fig. 1 shows a foam which has been produced with a Mondomix rotor-stator mixer, which is a standard commercially available device in the food industry for foaming products. In this device, gas is injected into a mixing chamber in which a rotor rotates at high speed and divides the gas into fine bubbles. Fig. 1 clearly shows that the bubbles have different dimensions. In Fig. 1, a 20% overrun was produced through addition of gas to protein solution (3% whey protein concentrate). The solution was thickened with 0.7% of xanthan gum to prevent creaming of the gas bubbles. In Fig. 1, the rotor speed was 1,000 rpm. The thus produced prefoam was then pumped through a membrane having an average pore size of 4 micrometers, at a rate of about 40,000 liters per m² per hour. This led to a pressure drop of 25 bar and the resultant monodisperse foam is represented in Fig. 2.

Example 2

In a second Example, the prefoam from Fig. 1 was pumped through a membrane having an average pore size of 8 micrometers. This involved a pressure drop of 10 bar at a flow rate of 40,000 liters per m² per hour. The resultant monodisperse foam is represented in Fig. 3a.
In the Example of Fig. 1, pressing the prefoam through the membrane requires 2.5 kJ of energy per liter of foam. To effect a similar decrease in bubble size with the Mondomix, about 500 kJ per liter of foam is needed. The thus produced foam is depicted in Fig. 3b.
A comparison of Fig. 3b and Fig. 3a shows that while both foams have a comparable average bubble size, the foam made with the membrane has a narrower distribution in bubble size. This is quantified in Fig. 3c. More particularly, Fig. 3c shows a quantification of the bubble size distribution, with the legend term "Mondomix" referring to the foam as shown in Fig. 3b and "membrane foaming" referring to the foam as shown in Fig. 3a. The y-axis plots the number of bubbles in a particular size category as a percentage of the total number of bubbles. Through both peaks, a normal distribution has been fitted, which shows the following for the average bubble size and standard deviation therein:

Membrane foam:: 30.4 ± 12.9 µm
Mondomix:: 35.4 ± 21.2 µm

Accordingly, membrane foams give a considerable improvement of the monodispersity (in other words, considerably reduce the (relative) standard deviation).
Fig. 4 shows the monodisperse foam from Fig. 2 after it has been stored for 3.5 hours.
Fig. 5 shows how the prefoam from Fig. 1 has modified in structure after one day of storage. It is to be noted here that the foam, through denaturation of proteins situated on the bubble surface and subsequent compression resulting from disproportionation, has been stabilized against further disproportionation. Accordingly, the bubbles can only shrink to a particular minimum size and after that remain stable. Clearly visible is that there is a wide distribution in the bubble size.
Finally, Fig. 6 shows a similarly stabilized foam after one day of storage, but the starting product was the foam from Fig. 2 which has been passed through a membrane of a pore size of 4 micrometers. Fig. 6 clearly shows that the bubble size in this foam is much more uniform and that there are only a limited number of large bubbles in the foam. As a result, the stability of the foam from Fig. 6 is particularly good.
It will be clear that the invention is not limited to the examples described and that various modifications are possible within the framework of the invention as defined by the claims.

Claims

A method for manufacturing a substantially monodisperse foam, wherein from an unfoamed liquid starting product, in a first foam forming step, a relatively coarse prefoam is formed which is insufficiently monodisperse, wherein the prefoam is passed through a membrane having a particular pore diameter to form a foam which is substantially monodisperse.
A method according to claim 1, wherein the average pore diameter of the membrane is chosen to be substantially 10 times smaller than the desired bubble diameter of the substantially monodisperse foam.
A method according to claim 1 or 2, wherein the prefoam is produced by a standard commercially available foaming device.
A method according to any one of the preceding claims, wherein in the prefoam at least substantially 20% gas is included.
A method according to any one of the preceding claims, wherein the starting product is a surfactant-containing composition.
A method according to any one of the preceding claims, wherein the viscosity of the prefoam is increased by adding to the starting product a thickener, such as, for instance, xanthan gum.
A method according to any one of the preceding claims, wherein the membrane is a sintered metal membrane, a ceramic or a polymeric membrane.
A method according to any one of the preceding claims, wherein the pore size of the membrane is in the range of 0.1-20 micrometers, more particularly in the range of 3-10 micrometers.
A method according to any one of the preceding claims, wherein the minimum bubble size in the prefoam is greater than about 5 times the average pore size.
A method according to any one of the preceding claims, wherein in the foamed product about 3-10 mg of protein are included per m² of bubble surface.
A method according to claim 10, wherein the protein in the bubble surface is in equilibrium with at least about 0.1 wt.% of protein in the liquid surrounding the bubbles.
A method according to any one of the preceding claims, wherein the starting product is a milk protein-containing edible liquid.
A method according to any one of the preceding claims, wherein the unfoamed starting product contains proteins which, after foaming of the product, are capable of forming a surface around the gas bubbles that is undeformable under the prevailing conditions by denaturing after adsorption to the bubble surfaces, followed by compression of the bubble surface.
A method according to claim 13, wherein the denaturation and the compression of the bubble surface take place after the foam has passed the membrane.
A method according to claim 13 or 14, wherein the rigid surface around the gas bubbles has been formed through heating of the foamed product followed by compression.
A method for imparting a particular taste sensation to an edible foamed product utilizing the method according to any one of the preceding claims, wherein the taste sensation is set through a suitable choice of the bubble size of the foam, wherein this bubble size is determined by choosing the pore size of the membrane to be about 10 times smaller than the desired bubble size.
A product obtainable with the method according to any one of the preceding claims